Hey statman, 

Thanks a lot for your suggestions. 

I think that the sequential approach sounds like a good idea. Since the people I am helping with this design would like to know which of the stabilizers and fiber types work best. I guess the split-plot is also needed for the base categorial factor. The the design would be the following: 

Then a follow-up question regarding setting up a future mixture design afterwards. 

Let's say we find that a specific stabilizer and fiber work best. Then you could also introduce a new ingredient (like protein). But I guess you can not augment this design into a mixture right? 
Another question is then, could you add the 3-5 runs from the first design to the mixture design as "extra" runs? 

I'm not sure what you mean "introduce a new ingredient"?  Why don't you include this in the study to start?  Is this a new formulation?  Was this "protein" already present, just not manipulated?  Conclusions you draw from any experiment are contingent on the inference space.  While adding factors in subsequent iterations is always an option, realize that conclusions you drew from previous experiments may no longer be valid (e.g., new interaction effects may impact the conclusions).

When adding data from previous experiments to new experiments you must be aware of the "block" effect.  What factors/conditions changed between the first and second experiment? (e.g., raw materials, ambient conditions)

You have gotten some good advice from @statman .  I have only two things to add. One thing is that if you have process variables (in your case, your categorical variables) and mixture variables, then you SHOULD cross the process variables with the mixture variables. This will allow you to see if any mixture effects change when you change those process variables -- a very real concern, otherwise why put the process variables into the design?

The other point that I will make is that you might be able to avoid the mixture scenario all together. Since one of your ingredients will be water, you could consider that inert. Ignore it, and that will allow you to treat the other mixture ingredients as "continuous" variables and you will be back into the realm of more traditional experimental design and modeling. You may not want to do that, but it is at least an option to point out.

Hi Dan, 
Thanks a lot for commenting. 

Yes, I am aware that you should cross the process and mixture variables. However in this case for example with the two categorial factors: Fiber type and Stabilizer Type. We expect based on domain knowledge that they should not interfere with each other. Is it then never "okay" to remove certain terms to simplify the model and get fewer runs?? 

Yes, that is a very valid point. I guess I was just really eager to try the mixture design approach after attending several courses. 

@Bertelsen92 , I am not saying that you must include all 2-way interactions. However, I think it would be important to put the Stabilizer Type*Stabilizer conc. and the FiberType*Fiber conc. interactions in the model. And to go one step further, the "interactions" in a mixture model are actually estimating curvature. That fact along with the fact that mixture designs are really all about developing predictive models, I would recommend ALL 2-way interactions (and the special cubic terms), if at all possible. Too bad resources are not free to allow that! 

Hi again, 
The trials we run are rather expensive and the developer wants as few ingredients in the formulation as possible. 
So hopefully the current setup will solve the issues. However, if that is not the case we might need to test new ingredients like proteins.

But really good point that if the inference space changes in subsequent experiments by adding new factors or changing the levels of existing factors, the conclusions drawn from previous experiments may no longer be valid. But I guess a categorial factor called Protein type as well as a continuous factor with the concentration could be added with levels like: Protein A, Protein B or Non-protein. Then all previous experiments would be "non-protein" at 0%? 

How would you tackle the above regarding the "block effect"?